Mechanical Valves for On‐Board Flow Control of Inflatable Robots

Jin, Lishuai; Forte, Antonio Elia; Bertoldi, Katia

doi:10.1002/advs.202101941

Cited by 26 publications

(17 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It yields 10 times enhanced bending speed and achieves a fast locomotion speed of 1.04 BL/S under low actuation frequency of about 0.5 Hz and low electrical power of 0.22-0.26 W (Figure 12B). [200,202] Spherical shell Soft swimmer [218] Soft jumper [220] Soft gripper [104] Spherical shell (bistable valve) Autonomous gripper [222] Soft oscillator [222,223] Soft rolling robot [223,224] Logic gate [76,223] Autonomous crawler [222] Soft quadruped robot [225] Compliant mechanism (linkage) Soft galloping robot [68] Fast swimmer [68] Balloon-based systems Quadruped robot [240] Fast-responsive soft actuator [120,121] Electroactive polymers Constrained 1D beam Dielectric Flexible gripper [198] 2D curved plate Fast object capture [211] Balloon [71] Soft and adaptive gripper [71,241] Soft actuator with large deformation [242] Stimuli-responsive polymers: Liquid crystal polymers Constrained 1D beam Light Soft snapper [178,162] Soft crawler on ground and/or underwater [180,181] Soft oscillator [184] Curved 2D plate Soft jumper [209] Hydrogels Constrained 1D beam Solvent Soft jumper [193,194] Soft logic gates [194] Based on the pre-curved bistable composite beam with an attached rubber band to remove the doubly clamped boundary condition for energy storage and release, Sun et al [196] used the embedded electrical-driven twisted-and-coiled actuators (TCAs) as artificial muscles to drive...…”

Section: Contact-based and Tethered Actuationmentioning

confidence: 99%

“…Continued. SMP-magnetic particle composite Light and magnetic [191] Magnetic particle-PDMS composite Magnetic [187] 3D dome shell [230] Hydrogel Temperature, light, or pH [229] Fast-responsive soft actuators Balloons Latex or rubber Pneumatic [120,121] Dielectric membrane Dielectric [242] Soft crawler (on ground) Pre-curved beam constrained by frame Liquid crystal networks Light [180] Silver nanowire-PDMS composite Electrical (Joule heating) [195] Links with pre-tensioned spring Ecoflex and 3D printed flexible links Pneumatic (passive) [68] Waterbomb origami PEDOT:PSS Humidity [75] Kresling origami Paper Motor [117,237] Soft crawler (underwater) Pre-curved beam constrained by frame Liquid crystal gels Light [181] Autonomous crawler 3D dome-based bistable valve Dragonskin elastomer Pneumatic [222] Soft roller [223,224] Soft quadruped robot [225] Balloons Latex [240] Soft swimmer 3D dome shell Ecoflex [218] Links with pre-tensioned spring [68] Modified von Mises truss SMP and 3D printed truss Temperature [69] Soft jumper (on ground) Singly clamped pre-curved strip Hydrogel Solvent [193] Pre-curved strip constrained by spring Twisted-and-coiled nylons Electrical (Joule heating) [196] Tilted beams Hydrogel and PDMS Solvent [194] Cylindrical plate Azo-liquid crystal network Light [209] Spherical shell with circular grooves PDMS Evaporation of hexane solvent [228] Two bonded spherical caps Elite double 32, 8 Pneumatic [220] Linkage with SMA spring Rigid frame with SMA spring Electrical [70] Soft jumper (on or under water)…”

Section: Temperaturementioning

confidence: 99%

“…They envision that based on the rich multistable behavior, the patterned dome structure can enable in situ decision-making capabilities when mechanically interacting with the environments by integrating distributed sensing, computation, and reconfiguration into a single system. [104] Bistable Valve-Based Versatile Soft Robotics: The bistable dome structure can also be integrated as a soft bistable valve for flow regulation and control with other shape-changing structures to achieve electronic-free controls of diverse robotic functionalities, [76,[222][223][224][225] including flow control, soft oscillators, and autonomous control of soft robots such as crawlers and gripers. Bistable and multistable dome shell-based soft pneumatic actuators for diverse robotic functionalities.…”

Section: Pneumatic Actuationmentioning

confidence: 99%

“…The delaying phenomenon of oscillating pressure outputs enables several applications, including translation of a spherical object on a ring-shaped elastomeric track (Figure 15C-i), separation of particles manipulated by the ring oscillator (Figure 15C-ii), and a hexagonal roller with a soft frame controlled by the ring oscillator (Figure 15C-iii). Very recently, a similar hexagonal rolling robot integrated with the bistable valve was demonstrated by Jin et al [224] to roll bi-directionally with a single pressure input. Drotman et al [225] applied the concept of bistable soft valves to construct an electronic-free, soft pneumatic controlled quadruped robot as shown in Figure 15D Integrating bistable dome-based soft pneumatic valves for versatile soft robotics.…”

Section: Pneumatic Actuationmentioning

confidence: 99%

See 3 more Smart Citations

Bistable and Multistable Actuators for Soft Robots: Structures, Materials, and Functionalities

et al. 2022

View full text Add to dashboard Cite

Snap‐through bistability is often observed in nature (e.g., fast snapping to closure of Venus flytrap) and the life (e.g., bottle caps and hair clippers). Recently, harnessing bistability and multistability in different structures and soft materials has attracted growing interest for high‐performance soft actuators and soft robots. They have demonstrated broad and unique applications in high‐speed locomotion on land and under water, adaptive sensing and fast grasping, shape reconfiguration, electronics‐free controls with a single input, and logic computation. Here, an overview of integrating bistable and multistable structures with soft actuating materials for diverse soft actuators and soft/flexible robots is given. The mechanics‐guided structural design principles for five categories of basic bistable elements from 1D to 3D (i.e., constrained beams, curved plates, dome shells, compliant mechanisms of linkages with flexible hinges and deformable origami, and balloon structures) are first presented, alongside brief discussions of typical soft actuating materials (i.e., fluidic elastomers and stimuli‐responsive materials such as electro‐, photo‐, thermo‐, magnetic‐, and hydro‐responsive polymers). Following that, integrating these soft materials with each category of bistable elements for soft bistable and multistable actuators and their diverse robotic applications are discussed. To conclude, perspectives on the challenges and opportunities in this emerging field are considered.

show abstract

Section: Contact-based and Tethered Actuationmentioning

confidence: 99%

Section: Temperaturementioning

confidence: 99%

Section: Pneumatic Actuationmentioning

confidence: 99%

Section: Pneumatic Actuationmentioning

confidence: 99%

See 2 more Smart Citations

Bistable and Multistable Actuators for Soft Robots: Structures, Materials, and Functionalities

et al. 2022

View full text Add to dashboard Cite

show abstract

“…The problem has received renewed interest in the recent decade due to its relevance to a variety of applications, as witnessed by a series of recent studies on the continuum-mechanical modelling of aneurysm initiation in human arteries (Fu et al, 2012;Alhayani et al, 2013;Bucchi & Hearn, 2013a,b;Alhayani et al, 2014;Rodríguez-Martínez et al, 2015), on localized bulging under the additional effects of swelling (Demirkoparan & Merodio, 2017), viscoelasticity/chemorheology (Wineman, 2015(Wineman, , 2017, and electric actuation (Lu et al, 2015), on the development of 1D gradient models and analytical solutions (Lestringant & Audoly, 2018Giudici & Biggins, 2020), and on mechanisms of rupture (Hejazi et al, 2021). Inflated soft tubes are also increasingly being used in soft robotics (Usevitch et al, 2020;Jin et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Localised bulging of an inflated rubber tube with fixed ends

Guo¹,

Wang²,

Fu³

2022

Preprint

View full text Add to dashboard Cite

When a rubber tube with free ends is inflated under volume control, the pressure will first reach a maximum and then decrease monotonically to approach a constant asymptote. The pressure maximum corresponds to the initiation of a localised bulge and is predicted by a bifurcation condition, whereas the asymptote is the Maxwell pressure corresponding to a "two-phase" propagation state. In contrast, when the tube is first pre-stretched and then has its ends fixed during subsequent inflation, the pressure versus bulge amplitude has both a maximum and a minimum, and the behaviour on the right ascending branch has previously not been fully understood. We show that for all values of pre-stretch and tube length, the ascending branches all converge to a single curve that is only dependent on the ratio of tube thickness to the outer radius. This curve represents the Maxwell state to be approached in each case (if Euler buckling or axisymmetric wrinkling does not occur first), but this state is pressure-dependent in contrast with the free-ends case. We also demonstrate experimentally that localized bulging cannot occur when the pre-stretch is sufficiently large and investigate what strain-energy functions can predict this observed phenomenon.

show abstract

Engineering Kirigami Frameworks Toward Real‐World Applications

Jin,

Yang

2023

Advanced Materials

Self Cite

View full text Add to dashboard Cite

The surge in advanced manufacturing techniques has led to a paradigm shift in the realm of material design from developing completely new chemistry to tailoring geometry within existing materials. Kirigami, evolved from a traditional cultural and artistic craft of cutting and folding, has emerged as a powerful framework that endows simple 2D sheets with unique mechanical, thermal, optical, and acoustic properties, as well as shape‐shifting capabilities. Given its flexibility, versatility, and ease of fabrication, there are significant efforts in developing kirigami algorithms to create various architectured materials for a wide range of applications. This review summarizes the fundamental mechanisms that govern the transformation of kirigami structures and elucidates how these mechanisms contribute to their distinctive properties, including high stretchability and adaptability, tunable surface topography, programmable shape morphing, and characteristics of bistability and multistability. It then highlights several promising applications enabled by the unique kirigami designs and concludes with an outlook on the future challenges and perspectives of kirigami‐inspired metamaterials toward real‐world applications.

show abstract

Mechanical Valves for On‐Board Flow Control of Inflatable Robots

Cited by 26 publications

References 42 publications

Bistable and Multistable Actuators for Soft Robots: Structures, Materials, and Functionalities

Bistable and Multistable Actuators for Soft Robots: Structures, Materials, and Functionalities

Localised bulging of an inflated rubber tube with fixed ends

Engineering Kirigami Frameworks Toward Real‐World Applications

Contact Info

Product

Resources

About